TEMPORAL LOBE EPILEPSY AND GRAND MAL SEIZURES
Transcript of TEMPORAL LOBE EPILEPSY AND GRAND MAL SEIZURES
TEMPORAL LOBE EPILEPSY AND GRAND MAL
SEIZURES
Beáta Bóné, M.D.
PhD Thesis
Department of Neurology
Medical School of Pécs
University of Pécs, Hungary
Leader of the project: Prof. József Janszky M.D., Ph.D., DSc.
Leader of the program: Prof. József Janszky M.D., Ph.D., DSc.
Leader of Doctoral School: Prof. Sámuel Komoly M.D., Ph.D., DSc.
Pécs 2015
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TABLE OF CONTENTS
ABBREVATIONS .........................................................................................................................3
INTRODUCTION .........................................................................................................................4
Tempotal lobe epilepsy .............................................................................................................4
Generalised tonic-clonic seizure ................................................................................................5
Generalised tonic-clonic seizure and temporal lobe epilepsy .....................................................6
The hippocampus and hippocampal abnormalities ....................................................................6
Temporal lobe epilepsy, febrile seizure and hippocampal abnormalities ....................................7
AIMS .........................................................................................................................................8
METHODS .................................................................................................................................9
Methods in the case of first question ........................................................................................9
Methods in the cases of 2nd and 3rd questions ....................................................................... 10
RESULTS .................................................................................................................................. 12
1. Is there an association between febrile seizure and hippocampal damage independent of
epilepsy? Can simple febrile seizure causes hippocampal abnormalities? Are there any
hippocampal abnormalities in healthy patients 15-20 years after a simple febrile seizure ........ 12
2. What clinical/neuroimaging features can be differentiated between TLE patients who have
regular SGTCS and those who do not? ..................................................................................... 13
3. Is there an association between secondarily generalized seizures and preceding seizure
elements or clinical data? ........................................................................................................ 14
DISCUSSION ............................................................................................................................ 15
Febrile seizure and hippocampal abnormalities ....................................................................... 15
Generalised tonic-clonic seizure in temporal lobe epilepsy ...................................................... 16
SUMMARY OF THE THESIS ....................................................................................................... 19
PUBLICATIONS RELATED TO THE THESIS .................................................................................. 20
Publications ............................................................................................................................ 20
Persentations and posters ....................................................................................................... 20
OTHER PUBLICATIONS ............................................................................................................. 21
Publications ............................................................................................................................ 21
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Presentations .......................................................................................................................... 22
Posters .................................................................................................................................... 23
ACKNOWLEDGEMENTS .................................................................................................... 24
ABBREVATIONS
AI: asymmetry index
ABS: absolute value
APR: automatisms with preserved consciousness.
ARBS: ability to react before seizures
HS: hippocampal sclerosis
TLE: temporal lobe epilepsy
CPS: complex partial seizure
FS: febrile seizure
SGTCS: secondary generalised tonic-clonic seizure
SUDEP: sudden unexpected death in epilepsy
MTLE-HS: mesial temporal lobe epilepsy with hippocampal sclerosis
VNS: vagal nerve stimulation
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INTRODUCTION
Temporal lobe epilepsy
The prevalence of epilepsy is 0,5- 1%. 60-70% of adult drug resistant epilepsy
cases is temporal lobe epilepsy (TLE, Halász, 1997; Janszky et al, 2001). TLE begins in
childhood or in young adulthood (Janszky et al, 2004a). In clinical practice, TLE is
divided into two forms: mesial and neocortical (French et al, 1993; Ebner, 1994). The
new classification of ILAE (International League Against Epilepsy) makes no such
distinction, it uses exclusively mesial temporal lobe epilepsy with hippocampal sclerosis
(MTLE-HS) terminology as an independent epilepsy syndrome. (Berg et al, 2010)
The most frequent seizure type in TLE is the complex partial seizure which is
characterised by unconsciousness, manual and oral automatisms. Neither loss of
consciousness nor automatisms are mandatory elements of CPS. Automatisms can be of
wide variety: squelch, chewing, explorating movement, rhythmic knocking, playing
around with fingers, pedal, oral or ambulatory automatisms (Williamson et al, 1993;
Wieser et al, 2004). Secondarily generalised tonic-clonic seizure may rarely occur in
temporal lobe epilepsy. The interictal EEG often shows uni or bilateral fronto-temporal
spike focus (Willamson et al, 1993).
Hippocampal damage, especially hippocampal sclerosis (HS) is the most
common pathological abnormality in chronic epilepsy (Babb and Brown, 1987), which
can be associated with memory loss due to affecting the mesiotemporal structure.
More than fifty percent of patients with mesial temporal lobe epilepsy with HS
(MTLE-HS) had a history of febrile seizure (FS) in childhood (French et al, 1993;
Wieser et al, 2004). It is not clear whether the HS is a consequence or the cause of
afebrile or febrile seizure.
Drug resistant TLE can be treated by resective epilepsy surgery. The most
frequently used surgical procedure is the anterior temporal lobectomy. 60-90% of
patients who underwent resective epilepsy surgery will be seizure free in correct
surgical indication. The two most important parts of presurgical evaluation are the high
resolution MRI using epilepsy protocol and the video EEG monitoring lasting 2-5 days.
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Further treatment option is the vagal nerve stimulation (VNS) or deep brain
stimulation in the anterior nucleus of thalami (ANT DBS) if the resective epilepsy
surgery cannot be performed or is not effective (Müller et al, 2010, Fischer et al, 2010).
In Middle Europe, it was first applied at our centre (Bóné et al, 2012).
Generalised tonic-clonic seizure
Reviewing the literature of generalised tonic-clonic seizure (GTCS) there is only
a few study deals high scientific fastidiousness. The study of Theodore at al (1994)
investigating 120 GTCS of 47 patients is highlighted, which primarily focused on the
length and course of the seizure.
GTCS is divided into seven phases: 1. phase: simplex partial seizure. A 2.
phase: CPS or other focal, absence seizure. 3. phase is defined as onset of
generalization as the brief period between the antecedent seizure and remaining phases
of GTCS. it was often characterised by versive head or body movement or by
vocalisation. 4. phase This is the pretonic-clonic phase which is characterised by
clonic jerking, often irregular and asymmetric, preceding the tonic phase. It was termed
by „per ictal myoclonic state” by Gastaut and Broughton. 5. phase The tonic phase is
the sustained contraction of all body muscles. Some clonic jerking usually accompanied
the increased tone. 6. phase In this phase of „tremulousness”, recurrent decreases in
muscle tone begin to interrupt the tonic phase and very-high-frequency clonic jerking
begins. Gastaut and Broughton called it „vibratory” phase. The tonic phase, the
tremulous phase, and the final (clonic) phase may blend together in a continuum. 7.
phase This a phase of clonic jerking, which is defined as beginning when the jerks can
be timed and counted.
In the study of Theodore at al. the mean duration of GTCS (3-7. phases) was 62
second. Marked heterogeneity in GTCS phenomenology was present, only 27% of
seizures included all five phases. The clinical phenomena suggest that multiple cortical
and subcortical routes of spread may exist.
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Generalised tonic-clonic seizure and temporal lobe epilepsy
The typical seizure type in TLE is the CPS which can be generalised. In this case
we are speaking about secondarily generalised tonic-clonic seizure (SGTCS). The drug
resistance and GTCS are the major risk factors for sudden death (SUDEP) and seizure-
related fatal injuries. (Walczak et al, 2001).
SGTCS had a more pronounced impact on the postictal lowering heart rate
variability (a potential predictor for sudden cardiac death) than CPS, which might
explain why most SUDEP occurs after GTCS (Tóth et al, 2010).
It is important to screen patients suffering from TLE who are at risk for
transition from CPS to SCTCS. It is unknown why some TLE patients have potentially
life-threatening GTCS, while others have not.
To our knowledge, Rektor et al (2009) were the only ones who investigated the
transition from focal-onset seizure to SGTCS, but they exclusively focused on
electrophysiological findings. One of the unanswered questions is why some focal
seizures propagate to SGTCS, while others do not.
The hippocampus and hippocampal abnormalities
Hippocampal damage and especially hippocampal sclerosis is the most common
pathological abnormality in TLE.
Hippocampal sclerosis means neuron loss and secondarily astroglia proliferation.
Is is clearly visible in high resolution MRI using epilepsy protocol: atrophy, T2 and
FLAIR signal enhancement, T1 signal degradation, internal structure blurring, temporal
horn dilatation, fornix and corpus mamillare atrophy (Barsi et al, 2000; Barsi,2001). The
affected regions in HS are CA1, CA3 regions and endfolium (Diehl B. et al 2000; Babb
and Brown, 1987).
The most often developmental abnormality is the isolated hippocampal
malrotation (HIMAL), wich was first described by Péter Barsi (Barsi et al, 2000). It
may not be the cause of epilepsy itself, but may indicate developmental abnormalities or
damage of the affected hemispherium.
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Temporal lobe epilepsy, febrile seizure and hippocampal
abnormalities
A history of febrile seizures is frequent in mesial temporal lobe epilepsy. Febrile
seizures occur in 2-5% of the population. There are two type of febrile seizures: simple
and complex. Simple febrile seizures are shorter than 15 minutes and show no focal
signs. Conversely, complex febrile seizures are longer than 15 minutes and can show
focal origin. Febrile seizures can appear as status epilepticus in 5% of cases (Ahmad
and Marsh, 2010).
70% of TLE patients with HS have febrile seizure in childhood. (French et al,
1993).
It is not clear whether the HS is a consequence or the cause of afebrile or febrile
seizures (Cendes at al, 1993) and the relationship between TLE, HS and febrile seizure
is also unclear. There are numerous studies investigating this relationship resulting in
numerous theories
(1) One of these theories, the hippocampal damage is caused by FS and after this
initial damage a synaptic reorganization takes place in the hippocampus, which
progressively evolves into HS, and this latter is the final cause of epilepsy
(Maher&McLachlan, 1995).
(2) It is possible that febrile seizure, HS and later consequence the TLE are
independently created and developed, it is backed to same aetiology.
Kasperaviciute at al (2013) suggested that genetic predisposition is responsible
for combined incidence of TLE, HS and febrile seizures. They found a mutation of
SCN1A gen in the MTLE patient who had febrile seizure in childhood and it was not
present after febrile seizure without epilepsy.
(3) In a third theory, a hippocampal abnormality (probably dysgenesis) generates
FS, and FS causes HS in the already affected hippocampus. (Fernandez et al, 1998;
Barsi et al, 2000).
(4) Fourth option: The pre-existing HS causes both FS and TLE. This theory is
the most improbable (Davies et al, 1996; Bower et al, 2000).
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AIMS
We were intended to answer the following questions:
1. Is there any association between febrile seizures and hippocampal
damage without presence of epilepsy? Can simple febrile seizures cause
hippocampal abnormalities? Are there any hippocampal abnormalities in
healthy people 15-20 years after suffering a simple febrile seizure?
2. What clinical/neuroimaging features can be differentiated between TLE
patients who regularly have SGTCS and those who do not?
3. Is there an association between secondarily generalised seizures and
preceding seizure elements as well as clinical data?
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METHODS
Methods in the case of first question
Advertisements on the notice boards at the various faculties of the University of
Pécs invited the participation of healthy students/postgraduates who had suffered at
least one FS in childhood, which they could prove by medical reports and who had no
epilepsy. After their written informed consent had been given, an MRI investigation
was planned.
Finally, the remaining 8 subjects with simple FS (FS+ subjects) were included.
They were blindly paired with regard to age and sex with 8 control subjects (FS-
subjects), who were also students or postgraduates and neither the subjects nor their
parents were aware of any episode of febrile or afebrile seizures.
MRI examinations
- Visual inspection
- MRI Volumetry
- T2 relaxometry.
The MRI examinations were performed on a 1-Tesla Siemens Magnetom
Harmony MRI machine (Siemens AG, Erlangen, Germany). We used the same MRI
protocol in all subjects: T2-weighted axial, FLASH 3D T1-weighted, T2-weighted,
FLAIR, and multi-contrast spin-echo sequences were made. The visual inspection was
performed by a neuroradiologist (P.B.), who was blinded to the clinical data and was not
present at the time of MRI examination.
For the MRI volumetry, the pictures were normalized by SPM-5 software in the
standard MNI space (Friston et al., 1995). The volumetry was performed on the T1-
weighted 3D FLASH images. For the automatic volumetry, IBASPM (Individual Brain
Atlases using SPM) was used to determine the hippocampal volume in vivo (Fischl et
al., 2004). The asymmetry between the volumes of the two hippocampi was
characterized by the absolute value of the asymmetry index: ABS(AI) = ABS((lHV –
rHV)/(lHV + rHV)) (l: left-sided, r: right-sided, HV: hippocampal volume, ABS:
absolute value function, AI: asymmetry index).
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For the T2 relaxometry, the equation of T2 relaxation (I = I0*exp(-TE/T2)) was
fitted to each signal alteration according to TE, in order to obtain the T2 value of each
voxel, thereby creating an individual T2 map for each subject. T1-weighted images
were coregistered to the individual T2 maps by using SPM-5. With the IBASPM,
individual brain atlases were created from the coregistered T1-weighted images, via
fitting to each individual T2 image. In these individual atlases, the hippocampus was
divided into three equal parts: anterior, middle and posterior parts. These individual
atlases were applied to the individual T2 maps in order to calculate the mean T2 values
of the parts of hippocampus in each subject.
Methods in the cases of 2nd and 3rd questions
In this retrospective study, we reviewed video-recordings and clinical data of 171
patients. The sample was comprised of patients who, due to drug resistance, had
consecutively participated in our adult presurgical evaluation program where they had
undergone ictal video-EEG recordings. All patients had a temporal lobectomy as a result
of mesial or neocortical (lateral)
TLE. When the patients were admitted to the
presurgical unit, a history of the SGTCS was taken and the SGTCS frequency was
ascertained by asking the patients (or in most cases their relatives) standard clinical
protocol questions directly. Patients underwent continuous video-scalp EEG monitoring
lasting more than 2 days. The electrodes were placed according to the 10-20 system. All
patients had high-resolution MRI examinations made on 1.5 or 1.0 Tesla Siemens
Magnetom MR machines (Siemens AG, Erlangen,Germany), using special protocol for
detecting epileptogenic lesions. 1-3 seizures per patient were included. SGTCS in the
patient history was defined if the patient had had more than one SGTCS on adequate
antiepileptic medication. We selected clinical, EEG and MRI features, as well as seizure
elements for the variables that were to be investigated for association with the presence
of SGTCS: e.g. ability to react before seizures, pure ictal vocalisation.
Conversely, we did not include those seizure elements that had a well-known
direct association with SGTCS (sign of 4, mouth deviation, head version) because they
would have provided redundant information and could not be put into multivariate
statistical models
For statistical evaluation of categorical variables, Chi-square and Fisher’s exact tests
were carried out. For evaluation of continuous variables, the Mann-Whitney test was
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performed. Error probabilities of <0.05 were considered to be significant. For
multivariate analysis, stepwise logistic regression was used. All statistics were
performed by the SPSS 15.0 software package (SPSS Inc., Chicago, IL).
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RESULTS
1. Is there any association between febrile seizures and
hippocampal damage without presence of epilepsy? Can simple
febrile seizures cause hippocampal abnormalities? Are there
any hippocampal abnormalities in healthy patients 15-20 years
after a simple febrile seizure?
Visual inspection
In 3 of the male subjects in the FS+ group, hippocampal abnormalities were
apparent on visual inspection: 2 cases of mild left-sided HS, and 1 of mild right-sided
HS and hippocampal dysgenesis on the left side. No FS+ women or FS- subject
exhibited hippocampal abnormalities.
MRI volumetry
The mean volume of the left hippocampus was 2.39±0.6 cm3 in the FS+ group and
3.01±0.8 cm3 in the FS- group. The difference was not significant (p=0.21). The mean
volume of the right hippocampus was 2.96±0.74 cm3 in the FS+ group and 3.62±0.72
cm3
in the FS- group, this difference showed a non-significant trend (p=0.093). The
mean total volume of the two hippocampi was 5.36±1.33 cm3 in the FS+ group and
6.63±1.46 cm3
in the FS- group. This difference showed also a non-significant trend
(p=0.069). As regards the volume asymmetry characterized by ABS(AI) values, there
was no difference between the two groups: ABS(AI) was 0.11±0.005 in the FS+ vs.
0.11±0.007 in the FS- subjects.
Gender differences
Women. The mean volume of the left hippocampus was 2.5 ±0.78 cm3 in the FS+
women and 2.32±0.18 cm3
in the FS- women. The mean volume of the right
hippocampus was 2.82±0.74 cm3 in the FS+ women and 2.9±0.4 cm
3 in the FS- women.
The mean total volume of the two hippocampi was 5.32±0.15 cm3 in the FS+ women
and 5.23±0.41 cm3
in the FS- women. These small differences were not significant.
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Men. The mean ages of the FS+ and the FS- men were identical (25.6±3.4 vs.
25.6±4.5, p=1.0). The mean volume of the left hippocampus was 2.34±0.6 cm3 in the
FS+ men and 3.43±0.9 cm3
in the FS- men (p=0.08). The mean volume of the right
hippocampus was 3.05±0.8 cm3 in the FS+ men and 4.05±0.48 cm
3 in the FS- men
(p=0.043). The mean total volume of the two hippocampi was 5.38±1.4 cm3 in the FS+
men and 7.48±1.14 cm3
in the FS- men (p=0.043).
There were no gender differences in the T2 relaxation time or ABS(AI), data not
presented.
T2 relaxometry
The T2 values in the anterior part of the left hippocampus and in the middle part
of the right hippocampus were elevated in the FS+ group
2. What clinical/neuroimaging features can be differentiated
between TLE patients who regularly have SGTCS and those who
do not?
If we consider the clinical data which were known before the video-EEG monitoring,
only the presence of hippocampal sclerosis on the MRI showed a positive association
with a history of SGTCS (Table 1). If we consider data obtained from video-EEG
monitoring, then the presence of pedal automatism and ictal speech showed a
negative association with a history of SGTCS, while the presence of SGTCS during the
video-EEG revealed a positive association.
In order to find out which variables were independently associated with a history of
SGTCS, we performed a stepwise logistic regression including those variables which
showed significant associations with a history on SGTCS on bivariate tests (logically,
we did not include the presence of SGTCS during the video-EEG). Logistic regression
showed that all of these three variables (hippocampal sclerosis, p=0.02; pedal
automatism, p=0.03; and ictal speech, p<0.001) independently associated with a history
of SGTCS
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3. Is there an association of secondarily generalized seizures
with preceding seizure elements and clinical data?
This question was focused on the seizures and not on the patients. The presence
of ARBS, oral and pedal automatisms, pure ictal vocalizations, ictal speech, and APR
showed a negative association with a presence of SGTCS during video-EEG
monitoring. At the same time, age, a history of SGTCS and sleep-onset seizures during
the video-EEG provided evidence for a positive association with SGTCS during video-
EEG monitoring.
In order to find out which variables were independently associated with the presence
of SGTCS during the video-EEG, we performed a stepwise logistic regression including
those variables which showed significant associations by bivariate tests (logically, we
did not include the history of SGTCS). Logistic regression found that age (p=0.038 d),
ARBS during video-EEG monitoring (p=0.007), oral automatisms (p=0.007), pedal
automatisms (p=0.005), pure ictal vocalizations (p=0.015), and APR (p=0.027) were
independently associated with the presence of SGTCS during video-EEG, while ictal
speech and sleep-onset seizures were not.
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DISCUSSION
Febrile seizure and hippocampal abnormalities
Our major findings are:
(1) Simple febrile seizures in childhood can be associated with hippocampal
abnormalities (elevated T2 relaxation time and volume reduction) in healthy highly-
educated adults who have never had afebrile seizures. A volume reduction has been
demonstrated only in men. In male subjects with a history of FS, we found significantly
smaller right-sided and total hippocampal volumes compared to the controls. Visual
inspection of MRI pictures revealed abnormalities in 3 of the 5 men with a history of
FS: all of them had mild HS, and one also hippocampal dysgenesis (HIMAL). No
abnormalities were found in the women, but the number of women involved was too
small to allow statistical conclusions. T2 relaxometry showed elevated T2 relaxation
time in FS+ group. Both the hippocampal volume is decreased and T2 relaxation time is
prolonged. These are suitable for the criteria of hippocampal sclerosis but the degree is
smaller than in classic drug resistant MTLE-HS patient.
(2) The different hippocampal abnormalities are not necessarily associated with
cognitive deficits. The all people in FS+ group and control people are student or
postgraduate student independently MRI showed hippocampal abnormality.
FS occurs in 2-5% of the population and carries an increased risk of subsequent
epilepsy with afebrile seizures, especially in cases of complex FS (Annagers et al.,
1979; Annagers et al., 1987). Conversely, MTLE-HS occurs in <0.2% of the population
(French et al., 1993; Wieser et al., 2004), and thus, only a minority of FS patients
subsequently exhibit MTLE-HS. Most FS children who go on to develop epilepsy have
simple FS (Nelson&Ellenberg; 1978). The short term and long term follow up studies –
which experiments the role of febrile seizure of developing HS- exclusively focused on
complex febrile seizure and it was performed in childhood.
In the present study, we investigated whether hippocampal abnormalities are
observed in healthy people 15-20 years after a simple febrile seizure. These people had
no cognitive impairment or epilepsy. In our healthy adult subjects with FS, the later
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development of MTLE-HS in unlikely because only ˂8% of MTLE-HS cases begin in
adulthood (Janszky et al 2004). Thus, our study has provided a strong argument that
hippocampal abnormality associated with FS is not always accompanied by epilepsy.
We found a hippocampal abnormality and volume loss only in male FS patients. In
TLE, the hippocampus seems to be more affected in men than in women (Briellmann et
al., 2000). This may be due to gender differences in the nature of the seizures. Men have
more serious and more frequently propagated seizures than women, or there may be a
gender-specific vulnerability of the hippocampus to the seizures in men (Briellmann et
al., 2000; Janszky et al., 2004).
The right-sided decrease in hippocampal volume in the FS subjects proved to be
more pronounced than that on the left side. Another prospective study after our
published study confirmed hippocampal sclerosis after FS is more frequent on the right
side (Shinnar et al, 2012).
Based on our investigation it can be assumed a relationship between febrile
seizure and hippocampal abnormality without rise to developing TLE. Hippocampal
sclerosis can develop without causes epileptic seizure or cognitive disturbance. Based
on our results we follow our investigation with iron sensitive MRI technique in healthy
FS people and epileptic patients with hippocampal abnormalities.
Generalised tonic-clonic seizure in temporal lobe epilepsy
The major findings of our study are:
(1) The presence of hippocampal sclerosis on MRI showed a positive association
with a patient’s history of SGTCS, while ictal speech and pedal automatism during
video-EEG recordings showed a negative association with a patient’s history of
SGTCS.
(2) The age of patients showed a positive association with a presence of SGTCS
during video-EEG monitoring, while ARBS, oral automatisms, pedal automatisms, ictal
vocalizations, and APR showed a negative association with a presence of SGTCS
during video-EEG monitoring.
The presence of hippocampal sclerosis on the MRI showed a positive association with
a patient’s history of SGTCS. Although we cannot fully explain this association, one of
the theoretical explanations may be that generalized seizures cause a more pronounced
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hippocampal injury than CPS or other focal seizures. There is early involvement of the
hippocampus when a focal seizure shows a transition to SGTCS (Rektor et al., 2009).
We cannot fully explain the association of age with secondary generalization.
Moreover, it was only true for generalization of seizures during video monitoring and
not according to the patient’s history. We can speculate that this association represents
the progressive nature of drug-resistant TLE (Jokeit et al, 1999; Fuerst et al., 2003;
Janszky et al., 2005).
There are no area which are thought to be unequivocally associated with pedal
automatism, although there may some hypothesis that it represents a seizure spreads in
the fronto-orbital areas (Swartz, 1994). Ictal speech automatism could be elicited by the
electrical stimulation of the amygdala (Driver et al., 1965). Talairach et al (1973)
suggested that oral automatisms during TLE seizures represent an involvement of the
anterior cingulum. We found that these ictal automatisms (speech, pedal and oral) are
associated with the absence of SGTCS, suggesting that amygdalar-orbitofrontal or
cingular seizure spread infrequently evolves to SGTCS or may even inhibit the
transition from focal seizures to SGTCS. Rektor et al (2009) found that during spread
from focal to generalised seizures in TLE, the cingulate and fronto-orbital cortex
showed slow activity on the stereo-EEG. They hypothesized that this slowing represents
inhibition in these regions, findings that are in accordance with our results.
In the present study, the ARBS and the APR (independent of each other) showed
a negative association with the secondary generalization. ARBS was associated with a
more circumscribed region involved at seizure onset since we found that ARBS was
associated with a lateralized seizure onset and a better outcome after TLE surgery. APR
is a well-known sign for non-dominant TLE seizure (Ebner et al., 1995) but also
indicates circumscribed seizure activity which strictly involves only one temporal lobe
without seizure spread to the contralateral side (Park et al, 2001; Janszky et al., 2003).
It seems reasonable to take a clinical approach that avoids SGTCS in the
monitoring unit because; due to the risk of injuries and SUDEP, it appears to be much
more dangerous than focal seizures without secondary generalization. Moreover,
through drug reduction, SGTCS can be artificially provoked and any complications
caused by provoked seizures can be considered to be an iatrogenic event. Thus, it may
be of high clinical value to assess the patomechanisms of the secondary generalization.
In the presence of risk factors for SGTCS, we might become more cautious in reducing
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drugs while monitoring presurgically. We could pay more attention to patients with a
high risk for secondary generalization by avoiding potentially dangerous situations (for
example when the video monitoring is paused). Detecting seizure elements that
represent a high risk for secondary generalization (for example, high age, the absence of
either oral automatism or ARBS) could help monitoring personnel be on alert for
SGTCS that might require immediate medical intervention.
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SUMMARY OF THE THESIS
1. We were the first who showed that simple febrile seizures in childhood may
be associated with hippocampal abnormalities in adulthood without presence of
epilepsy.
2. Hippocampal abnormalities are not always accompanied by cognitive
disturbance affecting everyday life.
3. TLE patients with presence of hippocampal sclerosis on MRI showed frequent
SGTCS. SGTCS are rarer in TLE patients who have CPS with automatisms. We
propose that these results should be taken into consideration during video EEG
monitoring: we can avoid grand mal seizure in the TLE patients who have a high risk
for secondarily generalization and therefore we can prevent severe complications.
4. Complex partial seizures can evolve to secondary generalised tonic clonic
seizures at a higher age. By contrast, in the presence of the ability to react before and
during seizure, automatisms and ictal vocalisation, the secondarily generalisation is rare.
This result confirms the hypothesis that in the process of secondarily generalisation, the
frontoorbital cortex and cingulum may be inhibited. We may hypothesize that the type
of the seizure spread at the beginning determines the later seizure spread.
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PUBLICATIONS RELATED TO THE THESIS
Publications
1. Bóné B, Fogarasi A, Schulz R, Gyimesi C, Kalmar Z, Kovacs N, Ebner A, Janszky J.
Secondarily generalized seizures in temporal lobe epilepsy. Epilepsia, 2012;53: 817-24.
Impact factor: 3.961
2. Auer T, Barsi P, Bóné B, Angyalosi A, Aradi M, Szalay C, Horvath RA, Kovacs N,
Kotek G, Fogarasi A, Komoly S, Janszky I,Schwarcz A, Janszky J. History of simple
febrile seizures is associated with hippocampal abnormlaities in adults. Epilepsia,
2008;49:1562-1569.
Impact factor: 3.733
Presentations and posters
Bóné B. Grand mal seizures in temporal lobe epilepsy (2011) 2nd Neuroscience
Symposium Pécs-Brno, Brno, Czech Republik, 2011.02.25
Bóné B, Fogarasi A, Schulz R, Gyimesi C, Kalmár Z, Kovács N, Ebner A, Janszky J
(2012) Másodlagosan generalizált rohamok temporalis lebeny epilepsziában Magyar
Epilepszia Liga XI. Kongresszus Kaposvár 2012.05.31-06.02.
Bóné B. (2012) Secondarily generalized seizures in temporal lobe epilepsy. 10th
European Congress on Epileptology, London 2012, London 30th September – 4th
October 2012 BEST POSTER
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OTHER PUBLICATIONS
Publications
Dávid M, Berki T, Bóné B, Magyarlaki T, Losonczy H (1999) Eosinophil sejtek
immunbiológiája és sejtes kölcsönhatásai idiopathiás hypereosynophil syndrómában / HES /
és secunder eosinophiliákban. Magyar Belorvosi Archivum 52: 359-367
Impact factor:-
Berki T, Dávid M, Bóné B, Losonczy H, Vass J, Németh P. (2001) New diagnostic tool
for differentiation of idiopathic hypereosinophilic syndrome (HES) and secondary
eosinophilic states. Pathol Oncol Res. 7:292-7.
Impact factor:-
Szűcs A, Lalit N, Rásonyi G, Barcs G, Bóné B, Halász P, Janszky J (2006) A hirtelen
halál és a mortalitás epilepsziában. Ideggyogy Sz 59:321-328.
Impact factor:-
Bóné B, Janszky J. (2006) Epilepsy and male sexual dysfunction: etiology, diagnosis
and therapy Ideggyogy Sz. 59: 148-52.
Impact factor:-
Janszky J, Pannek HW, Fogarasi A, Bóné B et al. (2006) Prognostic factors for surgery
of neocortical temporal lobe epilepsy. Seizure 15:125-32.
Impact factor: 1.384
Kovács N, Balás I, Llumiguano C, Aschermann Z, Bóné B, Tasnádi E, Nagy F, Janszky
J, Dóczi T, Varga D, Hollódy K, Karádi K, Illés Z, Komoly S (2008) Mély agyi
stimuláció - a disztónia kezelésének egy új perspektívája. Gyermekorvos továbbképzés
7:(Suppl A) 1-20
Impact factor:-
22
Deli G, Balás I, Komoly S, Dóczi T, Janszky J, Illés Z, Aschermann Z, Tasnádi E, Nagy
F, Pfund Z, Bóné B, Bosnyák E, Kuliffay Z, Szijjartó G, Kovács N. (2012) Treatment of
dystonia by deep brain stimulation: a summary of 40 cases Ideggyogy Sz 65:249-60.
Impact factor: 0.348
Gyimesi C, Bóné B, Tóth M, Horváth R, Komoly S, Janszky J (2013) Antiepileptic
drugs in treatment of epilepsy and follow up of their efficacy. Ideggyogy Sz 66:76-88.
Impact factor:0.343
Gyimesi C, Juhos V, Horváth R, Bóné B, Tóth M, Fogarasi A, Komoly Sl, Janszky J
(2013) Status epilepticus és kezelése - Update 2013 Ideggyógy Sz; 66: 372-82.
Impact factor: 0.343
Faludi B, Bóné B, Komoly S, Janszky J (2014) Az alvásfüggő légzészavarok és
epilepszia: kapcsolódási pontok és terápiás megfontolások. Ideggyógy Sz, közlésre
elfogadva.
Impact factor: 0.343
Presentations
Bóné B (1999) Eosinophiliás betegek eosinophil, T és NK sejtjeinek összehasonlító
elemzése, Tudományos Diákköri Konferencia Pécs, 1999.
Dávid M, Berki T, Bóné B, Losonczy H (1999) Idiopathiás és secunder eosinophiliás
állapotok differenciál diagnosztikája A Magyar Belgyógyász Társaság Dunántúli
szekciójának XLVI. Vándorgyűlése Zalaegerszeg, 1999.
Dávid M, Berki T, Bóné B, Magyarlaki T, Losonczy H. (1999) Áramlási cytometriás
módszerek alkalmazása az idiopathiás hypereosinophil syndroma (HES) és a szekunder
eosinophiliák elkülönítésére. Magyar Haematológiai és Transzfúziológiai Társaság
XVII: Kongresszusa Budapest, 1999.
Bóné B, Szapáry L, Szőts M, Komoly S. (2005) Rt-PA thromolysis ritka
szövődményeként fellépő fatalis alveolaris vérzés. Magyar Stroke Társaság VII.
Kongresszusa Eger 2005. Szept.
Kövér F, Bóné B, Garamszegi M, Hegedűs G, Szapáry L, Komoly S. (2005) Kétoldali
hallásvesztés a lehetséges okok áttekintése egy ritka eset kapcsán. Magyar
Neuroradiológiai Társaság XIV. Kongresszusa 2005. Szept. 23.
23
Bóné B, Horváth Zs, Gyimesi Cs, Deli G, Salamon Lászlóné, Karádi K, Barsi P, Gömöri
É, Ábrahám H, Komoly S, Dóczi T, Seress L, Janszky J. (2006) Epilepszia Sebészeti
Program Pécsett: az első év tapasztalatai. Magyar Epilepszia Liga Kongresszusa Pécs
2006. Május 25-27.
Ursprung Zs, Janszky J, Bóné B, Horváth Zs, Dóczi T. (2006) Epilepszia Sebészeti
Program Pécsett: az első év tapasztalatai. Magyar Radiológusok Társasága 23.
Kongresszusa. Osztrák-Magyar Radiológus Kongresszus 2006. Szept. 20-23.
Bóné B, Janszky J (2012) Progresszivitás az epilepszia kezelésében. III.
Neurstimulációs szimpózium, Pécs 2012.10.12-13
Bóné B, Balás I, Kovács N, Janszky J (2012) Epilepszia mélyagyi stimulációs kezelése
III. Neurostimulációs szimpózium, Pécs, 2012.10.12-13.
Bóné B. ANT DBS for epilepsy in Pécs Hungary (2013) 4th Medtronic DBS for
Epilepsy Ambassadors Meeting Bécs, Ausztria, 2013. Szeptember 27.
Bóné B, Kovács N, Balás I, Janszky J. (2014) Epilepszia DBS kezelése- saját eseteink
és update Magyar Epilepszia Liga XII. kongresszusa, Szeged, 2014. jún.5-7
Aschermann Zs, Ács P, Bóné B, Deli G, Kovács N. Ezerarcú dystonia (2014) Magyar
Tudományos Parkinson Társaság konferenciája 2014. május 23-24, Budapest
Perlaki G, Orsi G, Nagy Sz, Bogner P, Bihari K, Bóné B, Ács P, Komoly S, Aschermann
Zs. Az agyi vaslerakódás kvantitatív MR képalkotáson alapuló vizsgálata nyaki
disztóniában (2014) Magyar neuroradiológiai Társaság kongresszusa Hajdúszoboszló,
2014.november 6-7
Posters
Szapáry L, Bóné B, Szőts M, Komoly S. (2005) Rt-PA thrombolysis ritka
szövődményeként fellépő fatalis alveolaris vérzés. A 110 éves Magyar Ideg- és
Elmeorvosok Társaságának 34. Nagygyűlése. Szeged, 2005. Október 13-15
Szőts M, Nagy F, Bóné B., Nagy Á, Méhes G, Szapáry L, Mezey I, Tóth E. (2004)
Uncommon clinical presentation of parvovirus B19 infection. Congress of the
European Federation of Neurological Societies, 4-7 September, 2004, Paris, France,
Eur. J. Neurol. 11 (suppl 2) 321, 2004.
Bóné B., Berki T., Dávid M. (1998) Eosinophiliás betegek eosinophil, T és NK
sejtjeinek összehasonlító elemzése. Magyar Immunológiai Társaság XXVIII.
Kongresszusa Harkány, 1998.
24
ACKNOWLEDGEMENTS
First of all, I am greatly indebted to my supervisor Professor József Janszky,
who made me familiar with and made me like epileptology. I had the chance to study
the proper of evaluation EEG, video EEG, seizure semiology and the beauty of patient
care. I would like to thank him for all his help and inspiration.
I would like to express my gratitude to Professor Sámuel Komoly for his support
and for letting me work as a member of the epilepsy team.
I wish to thank Tibor Auer, András Fogarasi, Péter Barsi, Professor Tamás
Dóczi, Alois Ebner, Attila Schwarcz, Norbert Kovács, Zsolt Horváth, Ferenc Kövér and
Anna Angyalosi. I am more than happy for having had the chance to take part in the
very first special MRI examination carried out in the Diagnostics Centre Pécs.
My special thanks go to Péter Barsi for having introduced the basics of
neuroradiology to me.
I wish to thank all my colleagues for all their support and precious help.
I am grateful to my former colleagues Béla Csala, Ildikó Késmárky, Mónika
Szőts and Professor Ferenc Nagy
I wish to express my gratitude for Tímea Berki, Marianna Dávid and Tamás
Magyarlaki.
Last, but not least, I wish to thank my parents and my family for their support.